Systems and processes for fabricating dental restorations

ABSTRACT

A collaborative approach, incorporating a server for data transmission, security verification, and authentication verification, is implemented between a dental office and a dental laboratory to fabricate a designed dental restoration. A scanner is used in a dental office to take a scan of a patient&#39;s mouth. The dental laboratory designs the dental restoration with specialized design software taking into account the scan of the mouth as well as a prescription from the dental office. The parameters defining the designed dental restoration are contained in a design file. The design file is used to create milling specifications defining instructions for milling the designed dental restoration. The materials for the dental restoration are loaded into a mill, where the dental restoration is fabricated in accordance with the milling specifications. Security verification ensures authorized materials are used, and authentication verification ensures authorized materials and processes are used.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Patent ApplicationNos. 61/729,083 filed Nov. 21, 2012 and 61/767,571 filed Feb. 21, 2013,each of which are incorporated herein by reference in their entirety.

TECHNOLOGY FIELD

The present invention relates generally to fabricating dentalrestorations, and more particularly to fabricating dental restorationsusing a collaborative approach between a dental office and a dentallaboratory with security and authentication measures to verify the useof authorized materials and/or authorized processes.

BACKGROUND

Traditional methods for fabricating dental restorations involve adentist providing a dental laboratory with a physical impression of apatient's prepared tooth using impression materials or a digital scan ofa patient's prepared tooth generated by a scanner, such as an intra-oralscanner. The fabrication of the dental restoration is then preparedremotely at the dental laboratory, requiring the patient to return tothe dental office at a subsequent day to be fitted with the dentalrestoration upon receipt from the dental laboratory.

Other methods for fabricating dental restorations require a dentaloffice to purchase and maintain all of the equipment necessary forfabricating the dental restoration for a patient, including the scanner,the software for designing the dental restoration, and the mill and theassociated software for shaping and preparing the dental restoration.This method requires the purchase and maintenance of expensiveequipment, as well as ongoing training of dental office personnel.

This document describes systems and processes for fabricating dentalrestorations without the need to have multiple visits by a patient andwithout the costly equipment and training of personnel at a dentaloffice. This document further describes authentication and securityaspects for the fabrication of dental restorations to verify the use ofauthorized materials and/or authorized processes in fabricating thedental restorations.

SUMMARY

Embodiments of the present invention provide a system and a method forfabricating dental restorations in which a hybrid approach between adental office and a dental laboratory is implemented.

According to aspects of the invention, a server is configured tofacilitate communication between a dental office and a dentallaboratory. In an embodiment, the communication between the entitiesincludes: a scan file transmitted by the dental office to the dentallaboratory, the scan file comprising a scan of a patient, wherein thescan file is generated by a scanner located in the dental office; anddesign characteristics transmitted by the dental laboratory to thedental office, the design characteristics for a designed dentalrestoration associated with the scan file, wherein the designcharacteristics comprise at least one of (i) a design file definingparameters of the designed dental restoration and (ii) millingspecifications defining instructions for milling the designed dentalrestoration. A mill located at the dental office fabricates the designeddental restoration in accordance with the design characteristics.Although much of the disclosure herein is directed to an exemplarycentralized server, in other embodiments, the server functionality canreside locally, for example in a local PC and/or with local software.

In one embodiment, the design characteristics received by the dentaloffice comprise the design file defining parameters of the designeddental restoration. A computer-aided manufacturing (CAM) processor atthe dental office formulates the milling specifications from the designfile and provides the milling specifications to the mill for fabricationof the designed dental restoration. The design file defining parametersof the designed dental restoration is created by a computer-aided design(CAD) processor at the dental laboratory based upon the scan file and aprescription provided by the dental office. The prescription comprisesone or more of: (i) a tooth number; (ii) a type of dental restoration;(iii) a restorative material; (iv) a shade for the designed dentalrestoration and (v) medical data (e.g., patient name, doctor name, date,etc.). Additional information may also be included.

In another embodiment, the design characteristics received by the dentaloffice comprise the milling specifications defining instructions formilling the designed dental restoration, wherein a computer-aidedmanufacturing (CAM) processor at the dental laboratory formulates themilling specifications from the design file and provides the millingspecifications to the mill at the dental office for fabrication of thedesigned dental restoration. In this embodiment, the design filedefining parameters of the designed dental restoration is created by acomputer-aided design (CAD) processor at the dental laboratory basedupon the scan file and a prescription provided by the dental office.

According to an embodiment, the server is also configured to facilitateauthentication between the dental office and the dental laboratory,including verifying the scan file transmitted by the dental office andverifying the design characteristics transmitted by the dentallaboratory. Verifying the scan file comprises, according to anembodiment, the server confirming at least one of: (i) authenticity ofthe scan file; (ii) authenticity of a prescription associated with thescan file; and (iii) a pre-existing relationship between the dentaloffice and the dental laboratory. Verifying the design characteristicscomprises, according to an embodiment, the server confirming at leastone of: (i) authenticity of the design characteristics; and (ii) apre-existing relationship between the dental laboratory and the dentaloffice.

According to another embodiment, the server is further configured toverify the fabricated designed dental restoration, comprising:receiving, at the server from the dental office, information associatedwith the fabricated designed dental restoration; confirming, by theserver, that that fabricated designed dental restoration satisfiespre-determined conditions; transmitting, by the server, anauthentication of the fabricated designed dental restoration to thedental office; and printing, by an authentication processor at thedental office, an authentication indication associated with thefabricated designed dental restoration.

Other embodiments relate to verifying aspects relating to a dentalrestoration. According to an embodiment, a method includes: receiving,by a server coupled to a dental office and to a dental laboratory, oneor more identifiers from one or more of the dental office and the dentallaboratory, the one or more identifiers respectively relating to a frameof material for the dental restoration and a package of a plurality offrames; comparing, by the server, the one or more identifiers toauthorized identifiers stored in a database accessible by the server;comparing, by the server, data associated with the one or moreidentifiers to data contained in a corresponding prescription; andproviding, by the server to one or more of the dental office and thedental laboratory, authorization to proceed with the dental restorationif the one or more identifiers match the authorized identifiers and/orif the data associated with the one or more identifiers matches the datacontained in the corresponding prescription.

In an embodiment, the server determines a maximum yield related to theframe of material and a number of units of the maximum yield remaining.Authorization to proceed with the dental restoration is further based onat least one unit of the maximum yield remaining.

In an embodiment, providing authorization to proceed comprises theserver instructing a mill located at the dental office or the dentallaboratory to construct the dental restoration. If the one or moreidentifiers do not match the authorized identifiers and/or if the dataassociated with the one or more identifiers does not match the datacontained in the corresponding prescription, the server prevents a milllocated at the dental office or the dental laboratory from constructingthe dental restoration.

According to an additional embodiment, the server prepares a record filecomprising information from the dental office and the dental laboratoryrelating to the dental restoration; the server compares parameters ofthe record file to validation criteria stored in a database accessibleby the server; and the server provides, to one or more of the dentaloffice and the dental laboratory, an authorization certificationindicating approval of the dental restoration if the parameters of therecord file match the validation criteria.

In an embodiment, the record file comprises one or more of: dentistidentifier, case identifier, patient identifier, tooth number, type ofrestoration, scan file, design file, scanner model, CAD software,material parameters utilized in CAD, material type, and mill model. Thevalidation criteria comprise one or more of: validated scanner models,validated material parameters, validated material types, and validatedmill models.

According to an embodiment, the server stores the authorizationcertification and associates the authorization certification with one ormore of the dental office, the dental laboratory, and a patient for whomthe dental restoration is intended.

In another embodiment, the server associates the one or more identifierswith identification information of the one or more of the dental officeand the dental laboratory, and maintains a record of the identificationinformation with data relating to the dental restoration.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other aspects of the present invention are bestunderstood from the following detailed description when read inconnection with the accompanying drawings. For the purpose ofillustrating the invention, there is shown in the drawings embodimentsthat are presently preferred, it being understood, however, that theinvention is not limited to the specific instrumentalities disclosed.Included in the drawings are the following Figures:

FIG. 1 is a block diagram representing a system for fabricating dentalrestorations, according to an embodiment;

FIG. 2 is a flowchart illustrating a method of fabricating dentalrestorations, according to an embodiment;

FIG. 3 is a block diagram representing a system for fabricating dentalrestorations, according to an additional embodiment;

FIG. 4 is a flowchart illustrating a method of fabricating dentalrestorations, according to an additional embodiment; and

FIG. 5 is a flowchart illustrating a method of verifying security andauthentication in the fabrication of a dental restoration, according toan embodiment.

DETAILED DESCRIPTION

Embodiments of the present invention relate to the incorporation ofauthentication and security aspects into systems and processes forfabricating dental restorations. According to embodiments, a scanner isused in a dental office to take a scan of a patient's mouth, a file ofwhich is sent to a laboratory, such as a dental laboratory. The dentallaboratory designs the dental restoration with specialized designsoftware taking into account the scan of the mouth as well as aprescription from the dental office. Parameters defining the designeddental restoration are contained in a design file. The design file isused to create milling specifications defining instructions for millingthe designed dental restoration. The materials for the dentalrestoration are loaded into a mill, located at the dental office, wherethe dental restoration is fabricated in accordance with the millingspecifications. This procedure allows for a same-day patient visit inwhich the patient is examined and fitted with the dental restoration.

The term “same-day patient visit” means a patient treatment period ofone calendar day. In some embodiments, the patient may be permitted toleave the dentist's office and return that same day. In otherembodiments, the same-day patient visit may be a single office visit.

The terms “single office visit”, “one office visit” or similar means asingle block of contiguous time. Because of the relatively short periodsinvolved, the patient need not leave the dentist's office and in someinstances not even leave the examination room. In some embodiments, asingle office visit may be about 3 hours or less, or about 2.5 hours orless, about 2 hours or less, about 1.5 hours or less, or less than 1hour, or any range between two of these values.

The term “dental office” as used herein means the patient's dentist'soffice. It is intended to mean the normal everyday working office of thedoctor.

The term “dental laboratory” as used herein means a professional dentallaboratory separate and distinct from a dental office. A dentallaboratory is an off-site facility for development and/or production ofdental restorations. For clarity, the dental laboratory does not installthe restorative devices, and does not perform the traditional functionsof a dental office.

FIG. 1 provides a block diagram illustration of a system 100 forfabricating dental restorations, according to an embodiment. The system100 includes a dental office 110, a server 120, and a dental laboratory130.

Features of the dental office 110 include a scanner 112, a mill 114, andan authentication processor 116. The scanner 112, such as an intra-oralscanner (IOS) or other scanner available in the dental industry, is usedto scan a patient, and, in particular, a prepared tooth of a patient. Adentist or other professional working at the dental office 110 preparesthe tooth to be fitted with a fabricated dental restoration. The dentalrestoration needs to be designed for the patient and to meet certainrequirements specified by the dentist.

The mill 114 is capable of milling (i.e., cutting and forming) thedental restoration. According to an embodiment, the mill 114 is acomputer numerical control (CNC) mill. The use of a CNC mill allows foran automated system in which computer-aided design (CAD) andcomputer-aided manufacturing (CAM) programs are used to create filesthat provide commands for the operation of the CNC mill.

The authentication processor 116 is configured to process informationassociated with the authenticity of the fabricated dental restoration,as described in greater detail below.

The system 100 for fabricating dental restorations also includes aserver 120 and a dental laboratory 130. The server 120 is configured tofacilitate communication between the dental office 110 and the dentallaboratory 130. The server 120 may be one or more dedicated servers fora particular entity or entities, or the server 120 may be one or moreservers that are part of a cloud-based server. The server 120 may bepart of a communication network. Examples of communication networksinclude, for example, a local area network (LAN), a wide area network(WAN), and the computers and networks forming the Internet. The server120 performs various verification, security, and authenticationprocesses before transmitting data to and/or between the dental office110 and the dental laboratory 130. The verification processes serve toensure that the dental office 110 and the dental laboratory 130 areauthorized to communicate with one another and to ensure that the datato be transmitted is valid and meets certain requirements. Moreover, thesecurity processes serve to ensure that authorized materials are usedfor the dental fabrications, while the authentication processes serve toverify that authorized processes are used in the fabrication. Furtherdetails related to the functionality of the server 120 are providedbelow.

The dental laboratory 130 is responsible for designing the dentalrestoration, taking into account the scan of the mouth as well as aprescription from the dental office 110. In the embodiment shown in FIG.1, the dental laboratory 130 includes a design processor 132 and amanufacturing processor 134. The design processer 132 may comprise CADsoftware for designing the dental restoration. The manufacturingprocessor 134 may comprise CAM software for formulating thespecifications to be used by the mill 114 for milling the dentalrestoration (i.e., the milling specifications).

In the embodiment illustrated in FIG. 1, the mill 114 located at thedental office 110 mills the dental restoration, while the dentallaboratory 130 is remotely providing the technology for the design ofthe dental restoration. In some embodiments, the dental laboratory 130may place the mill 114 in the dental office 110 based on a contractualrelationship between the dental office 110 and the dental laboratory130. In this embodiment, the dental office 110 does not have to investin the design technology but still achieves a same-day patient visit,which may be one-hour or less in duration.

In this embodiment, the mill 114 functions in a similar manner as aremote printer, in that it does not require any kind of design software(e.g., CAD) in the dentist office 110. In fact, there is little hands-onintervention in the dentist office other than placing a restorativematerial in the mill 114. The dental laboratory 130 remotely controlsthe mill 114, minimizing or eliminating the need for any kind ofintervention on the dentist side in the design and fabrication of thedental restoration.

In other embodiments, a separate mill may also be provided at the dentallaboratory 130.

FIG. 2 provides a data flow representation 200 of a method offabricating dental restorations, according to an embodiment. The dataflow begins at the dental office 110 with, at 210, a prepared toothbeing scanned with the scanner 112 to create a scan file containing athree-dimensional image. At 220, a prescription is prepared, theprescription being associated with the scan file. The prescription mayinclude details related to the dental restoration to be designed andfabricated, such as, but not limited to, a tooth number; a type ofdental restoration, such as, for example, inlay, onlay, crown, andbridge; a restorative material, such as, for example, ceramic,Nano-resin, zirconia, and composite materials; a shade for the designeddental restoration, such as, for example, Vita A1-D4; and a manufacturerand/or brand name. The prescription may also include information relatedto the patient, such as, but not limited to, a patient name, patientdemographic information, and patient medical information. Otherinstructional or identifying information may be included with theprescription.

At 225, the scan file and the prescription are sent from the dentaloffice 110. At 230, the server 120 verifies the scan file and theprescription. At 235, the verified scan file and prescription are sentto the dental laboratory 130. Details relating to the verification ofthe scan file and the prescription are provided in greater detail below.

At 240, the design processor 132 at the dental laboratory 130 determinesthe design characteristics for a dental restoration associated with thescan file. The design characteristics may be in the form of a designfile defining parameters of the designed dental restoration and may becreated by CAD software running on the design processor 132. Inparticular, a trained dental laboratory technician uses the CAD softwareto examine and manipulate the three-dimensional image in the scan fileto define the characteristics and physical parameters of the designeddental restoration. The designed dental restoration is designed tosufficiently meet the functional and aesthetic needs of the patient,which are defined in the prescription.

At 245, the design file is transmitted from the design processor 132 tothe manufacturing processor 134, also at the dental laboratory 130. At250, the manufacturing processor 134 formulates the millingspecifications that define instructions for milling the designed dentalrestoration. As noted above, CAM software may be running on themanufacturing processor 134. The CAM software defines how the mill 114will mill the designed dental restoration from a material provided inthe mill 114. The mill 114 utilizes a series of tools or burs to shape adental material into the designed dental restoration, and the CAMsoftware may be programmed, according to an embodiment, to define thefollowing mill specifications: (i) cutting tools or burs utilized by themill 114 and their positions within the mill 114; (ii) athree-dimensional geometry of the material to be milled; and (iii) tooland tool path strategies to achieve the designed dental restoration.

At 255, the milling specifications are sent from the dental laboratory130. At 260, the server 120 verifies the milling specifications, and, at265, transmits the verified milling specifications to the dental office110. Verification of the milling specifications may generally relate toensuring the specifications adhere to the prescription. Details relatingto the verification of the milling specifications are provided ingreater detail below.

At 270, the mill 114 located at the dental office 110, fabricates thedesigned dental restoration in accordance with the millingspecifications.

When the verified milling specifications are provided to the dentaloffice 110, the dental office 110 may be alerted that the mill 114 isready to begin a fabrication. This may be done through a processor orcontroller associated with the mill 114. For example, a message may beretrieved or a signal activated, indicating the prescription associatedwith the fabrication and the restorative material to be used. Anoperator at the dental office 110 loads and secures the restorativematerial into the mill 114, and then the fabrication may be initiated.

When the fabrication is completed, the mill 114 may provide a signalindicating completion, at which point the fabricated designed dentalrestoration is unloaded from the mill 114, and an operator, such as thedentist, performs minor finishing procedures to the fabricated designeddental restoration to prepare for seating in the patient's mouth.

In some embodiments, a security step involving material authenticationcan be incorporated into the process. An optional authenticationrelating to the process and parameters used to create the fabricateddesigned dental restoration may also be done. With further reference toFIG. 2, at 275, information associated with the fabricated designeddental restoration is sent from the authentication processor 116, incommunication with the mill 114, at the dental office 110 to the server120. The information may include, but is not limited to, the restorativematerial, the manufacturer and/or brand of the restorative material, andthe milling strategy as outlined in the milling specifications. At 280,the server 120 uses this information as well as the scan file, theprescription, and the design file to determine if requirements andstandards are satisfied. At 285, if the server 120 determines that therequirements and standards are satisfied, an authentication message issent to the authentication processor 116. At 290, the authenticationprocessor 116 may print an authentication, such as a label or otheridentifier, through an associated printer. Additionally oralternatively, the requirements and standards, including theauthentication of the requirements and standards, may be stored in adatabase or table accessible by the server 120 and may be established toindicate that the fabricated designed dental restoration is sufficientas defined by the requirements and standards. The security process andadditional details related to the authentication process are furtherdescribed below with respect to FIG. 5.

In some embodiments, prior to fabricating the designed dentalrestoration at 270, the dental office 110 may provide data associatedwith the restorative material to the server 120 to verify that thecorrect material (i.e., the prescribed material) is being used. In someembodiments, if the server 120 identifies that the correct material isnot being used, the server 120 may prevent the mill 114 from milling thedental restoration. If the correct material is being used, thefabrication and subsequent authentication steps may be implemented asdescribed above. Additional details related to this security step aredescribed below with reference to FIG. 5.

The verification of the data, i.e., the scan file and prescription at230 and the milling specifications at 260, by the server 120 may includethe server 120 confirming the authenticity of the scan file, theprescription, and the milling specifications, as well as confirming apre-existing relationship between the dental office 110 and the dentallaboratory 130. In confirming the authenticity of the scan file, theprescription, and the milling specifications, the server 120 may verifycertain features, such as, but not limited to: the dental office 110being a valid participant, the dental laboratory 130 being a validparticipant, the scan file containing sufficient information forcreating a design file and/or the milling specifications, theprescription containing sufficient information for creating the designfile and/or the milling specifications, and the milling specificationsbeing complete. In the verification of the data, the server 120 mayaccess stored information, such as valid participants and requirementsfor the scan file, the design file, and the milling specifications; theserver may also store the scan file, the design file, and/or the millingspecifications at an accessible memory device (not shown).

FIG. 3 provides a block diagram illustration of a system 300 forfabricating dental restorations, according to an additional embodiment.The system 300 includes a dental office 310, the server 120, and adental laboratory 330. The main differences between the systems 100 and300 are the location of the manufacturing processor that runs, accordingto an embodiment, the CAM software for formulating the millingspecifications based on the design file. In the embodiment shown in FIG.3, the dental office 310, in addition to including the scanner 112, themill 114, and the authentication processor 116, includes themanufacturing processor 118. In this embodiment, the dental laboratory330 still includes the design processor 132 for creating the design filebased on the scan file and the prescription. The dental laboratory 330transmits the design file, via the server 120, to the dental office 310for the formulation of the milling specifications via the manufacturingprocessor 118.

FIG. 4 provides a data flow representation 400 of a method offabricating dental restorations, according to an embodiment. At 410, aprepared tooth is scanned with the scanner 112 in the dental office 310to create a scan file containing a three-dimensional image. At 420, aprescription is prepared, the prescription associated with the scanfile.

At 425, the scan file and the prescription are sent from the dentaloffice 110. At 430, the server 120 verifies the scan file and theprescription. At 435, the verified scan file and prescription are sentto the dental laboratory 330.

At 440, the design processor 132 at the dental laboratory 330 determinesthe design characteristics for a dental restoration associated with thescan file. The design characteristics may be in the form of a designfile defining parameters of the designed dental restoration and may becreated by CAD software running on the design processor 132.

At 445, the design file is transmitted from the design processor 132. At450, the server 120 verifies the design file, and, at 455, transmits theverified design file to the dental office 310.

At 460, the manufacturing processor 118 at the dental office 310formulates the milling specifications that define instructions formilling the designed dental restoration. At 465, the millingspecifications are provided to the mill 114 for fabrication of thedental restoration. At 470, the mill 114 located at the dental office310, fabricates the designed dental restoration in accordance with themilling specifications.

At 475, information associated with the fabricated designed dentalrestoration is sent from the authentication processor 116, incommunication with the mill 114, at the dental office 310 to the server120. At 480, the server 120 uses this information as well as the scanfile, the prescription, and the design file to determine if therequirements and standards are satisfied. At 485, if the server 120determines that the requirements and standards are satisfied, anauthentication message is sent to the authentication processor 116. At490, the authentication processor 116 prints an authentication, such asa label or other identifier. In addition to or alternative to printingan authentication label or identifier, the server 120 may store anindication of the authentication in a database or table accessible bythe server 120. The indication of the authentication may be establishedto indicate that the fabricated designed dental restoration issufficient as defined by the requirements and standards. Moreover, theauthentication may be associated with a patient-specific and/or a dentaloffice account. In this manner, a record may be created and linked tothe patient and/or the dental office 310 to indicate the various dentalrestorations associated with the patient and/or the dental office 310.

According to embodiments, a security process is used to verify the useof authorized materials in the dental mill, and an authenticationprocess verifies that an authorized process and prescribed materials areused to create the dental restoration.

According to an embodiment, each frame containing restoration materialhas an identifier, e.g., a barcode that provides information such as,but not limited to, manufacturer or brand, material type, size, shape,color, shade, etc., with respect to the blank to be milled. Othertechnical information may be associated with the identifier dependingupon the material. The identifiers are stored in a database in oraccessible to the server 120. Each identifier may be assigned a maximumyield in units based on the type and size of the material contained inthe frame. Each time a restoration is ready to be fabricated, prior tomilling, a dental office or dental laboratory personnel scans theidentifier, which is sent to the server 120. The server 120 verifies ifthe identifier exists in the database, serving as an indication that thematerial is authorized for use. The server 120 may also verify if thescanned identifier matches that indicated in the milling instructions orthe dentist prescription. In the event the identifier does not exist ordoes not match that required by the milling instructions, an audible,visual or other alert is issued at the dental office 110, 310 to alertpersonnel that the material is not authorized or that the materials donot match those prescribed by the dentist (e.g., incorrect brand ormanufacturer or incorrect material). In some embodiments, the mill 114may be prevented from working on a non-authorized material. In someembodiments, the dental office or laboratory personnel may be permittedto override the alarm and prepare the restoration from an alternativematerial. With respect to the maximum yield, the server 120 confirmsthat the maximum yield has not yet been met for a particular identifier.If the maximum yield is not met, the server 120 verifies the materialand subtracts a unit from the maximum yield. In this manner, the maximumyield check adds an extra layer of security by prohibiting subsequentuse of the frame by the dental office 110, 310 or dental laboratory 130,330 adding material to a frame whose original material has beenexhausted.

According to an additional embodiment, a further security check may beincorporated by adding a shipment code to a plurality of frames, withthe shipment code identifying the customer (i.e., the dental office 110,310 or the dental laboratory 130, 330) and the plurality of frames thatmake up a shipment/order/package. The various shipment codes are storedin database in or accessible to the server 120. In addition to scanningthe frame identifier, the dental office 110, 310 or the dentallaboratory 130, 330 may scan or enter the shipment code. The server 120verifies if the shipment code matches a code stored in the database, ifthe shipment code is associated with the dental office 110, 310 or thedental laboratory 130, 330 transmitting the shipment code, and if theshipment code is associated with the frame identifier also beingscanned. In this manner, the shipment code serves as an extraconfirmation that a valid user is utilizing the frame and material for adental restoration.

According to an additional embodiment, a dental office 110, 310 or adental laboratory 130, 330 may purchase materials with a license to usea predetermined number of units of the material. An account may becreated and stored relating to this arrangement. The material does nothave a frame identifier but may still be authorized by the server 120confirming that an account is established and that the predeterminednumber of units has not been exhausted.

According to yet another embodiment, identification information, such asgeographic information, may be associated with the purchaser (e.g., thedental office 110, 310) of restoration materials. The identificationinformation of the purchaser may be linked to the identifier, e.g., thebarcode, of the material. When the identifier is scanned and sent to theserver 120 during the fabrication process, the server 120 maintains arecord of the identification information linked to the particularmaterial being used. In this manner, records of the users of thematerial are linked to the actual material, which may be of interest tothe manufacturer or sales associates. For example, if the identificationinformation is, as one example, a zip code of the dental office 110, 310using the restoration material, the server 120 will compile a listing ofzip codes that used materials by a certain manufacturer. The server 120may provide this information to various entities, such as manufacturers,sales associates, etc. Moreover, the identification information is notlimited to geographic information (e.g., zip code, area code, city,state, etc.) but may also include the type of facility (e.g., universityor private practice) or the size of the facility (based on, for example,the number of patients seen during a given time period or the number ofpractitioners).

FIG. 5 provides a data flow representation 500 of a method of verifyingsecurity and authentication in the fabrication of dental restorations,according to an embodiment. The method shown in FIG. 5 may incorporatethe features shown in FIGS. 2 and 4 and may serve as additional add-onfeatures. At 510 a, a shipment code is entered or scanned at the dentaloffice 110, 310. At 520 a, a frame identifier is entered or scanned atthe dental office 110, 310. Alternatively, at 510 b, a shipment code isentered or scanned, and at 520 b, a frame identifier is entered orscanned at the dental laboratory 130, 330. This entered/scannedinformation is sent to the server 120, where, at 530, a security checkis done to determine if the shipment code, frame identifier, and maximumyield associated with the frame identifier are secure. The server 120sends a security status to the dental office 110, 310 or to the dentallaboratory 130, 330 indicating if the material is authorized based onthe analyzed information.

During the processes described above with respect to FIGS. 1-4, variousinformation is provided to the server 120 from the dental office 110,310 and the dental laboratory 130, 330. For example, at 540, the scanfile, prescription, and/or the milling instructions are provided fromthe dental office 110, 310 to the server 120. At 550, the design fileand the milling specifications are provided from the dental laboratory130, 330 to the server 120. These pieces of information are nottypically sent at one time, but are instead sent and processed duringthe dental fabrication process as described above with respect to FIGS.2 and 4.

At 560, the server 120 uses the received information to create a recordfile. The record file may include one or more of: dentist identifier,case identifier, patient identifier, tooth number, type of restoration,manufacturer and/or brand of restoration material, scan file, designfile, scanner model, CAD software, material parameters utilized in CAD,material type, and mill model. Other relevant information may also beincluded.

At 570, the record file is compared against validation criteria storedin a database accessible to the server 120. The validation criteria maybe established to determine if the designed dental restoration meetscertain pre-approved criteria. The validation criteria may also includeinformation from the dentist prescription to ensure the prescription isbeing adhered to (e.g., the type of material, the manufacturer, etc.).The validation criteria may include, but is not limited to, one or moreof: validated scanner models, validated material parameters, validatedmaterial types, validated manufacturer and/or brand, and validated millmodels. Based on the comparison, the dental restoration process iseither authenticated or denied, and this status is sent to the dentaloffice 110, 310 and/or the dental laboratory 130, 330. The status mayalso be stored and saved with the record file to be later accessed aspart of a patient or office record. In some embodiments, as describedabove, an invalidated material and/or process may result in the mill 114being prevented from milling the dental restoration.

According to embodiments provided herein, while a scanner 112 is used ina dental office 110, 310 to take a scan of a patient's mouth, the designof the dental restoration is done offsite at a dental laboratory 130,330. The dental laboratory 130 formulates the milling specifications anddefines instructions for milling the designed dental restoration. Themilling specifications are formulated based on the scan received by thedental laboratory. In one embodiment, those milling specifications areused to define milling instructions at the dental lab 130 and which aretransmitted to the mill 114 at the dental office which receives remoteinstructions for formulating the designed dental restorations. Inanother embodiment, the milling instructions may be developed by dentallaboratory personnel on the CAM software resident at the dental office310, in which case the mill 114 communicates with the manufacturingprocessor 118 within the dental office 310. This procedure allows for asame-day patient visit in which the patient is examined and fitted withthe dental restoration. In other embodiments relating to security andauthentication aspects, the dental laboratory 130 may also include amill. Generally, the CAM software performs the two functions: 1)formulating the milling specifications, and 2) defining instructions forthe milling machine. These two functions may reside together in a singleCAM software, or separately. When separate, is possible that theformulating functionality may reside in the dental laboratory, while thedefining instructions functionality may reside in the dental office. Ineither case, the dental laboratory will control the operation of bothfunctions of this software directly or remotely. In this manner, thedental laboratory, and not the dental office, controls the formulationof the milling specifications as well as the milling instructions.

The processors 116, 118, 132, and 134 may be a processing device,computing device, or the like for performing calculations and operationsdescribed herein. As used herein, a controller or a processor should beunderstood to include any number of controllers or processors. While thecontroller and processors described herein have been broken down asindividual controllers and processors performing certain tasks, this isdone for illustrative purposes. Embodiments of the present invention caninclude single or multiple controller or processors performing the rolesdescribed. Furthermore, the roles described as separate controllers orprocessors herein can, in some embodiments, be performed by separate orcommon controllers or processors or any subset therein. The server 120includes one or more processors for performing the calculations andoperations described herein.

The processors 116, 188, 132, and 134 and the server 120 may interfacewith one another, and may also interface with one or more memorydevices, such as read only memory (ROM), random access memory (RAM), andone or more optional non-transitory memory devices such as, for example,an external or internal DVD drive, a CD ROM drive, a hard drive, flashmemory, a USB drive, or the like. The memory devices may be configuredto include individual files and/or one or more databases for storing anysoftware modules, instructions, or data.

Program instructions, software, or interactive modules for performingany of the functional steps associated with the processes as describedabove may be stored in the ROM and/or the RAM. Optionally, the programinstructions may be stored on a tangible computer readable medium suchas a compact disk, a digital disk, flash memory, a memory card, a USBdrive, an optical disc storage medium, such as a Blu-Ray™ disc, and/orother recording medium.

An optional display interface may permit information from the processors116, 188, 132, and 134 and the server 120 to be displayed on a displayin audio, visual, graphic, and/or alphanumeric format. For example, adisplay may be associated with the mill 114 to indicate to an operatordetails and instructions related to the fabrication of the designeddental restoration. Communication with external devices may occur usingvarious communication ports that may be attached to one or morecommunications networks, such as the Internet or a local area network,or directly to a portable computing device such as a notebook computer.An interface may allow for receipt of data from input devices such as akeyboard, a mouse, a joystick, a touch screen, a remote control, apointing device, a video input device, an audio input device, and thelike. Communications within the system or any part thereof or toexternal devices or systems can be achieved through any suitablearrangement, including but not limited to wired or wirelesscommunications or combinations thereof.

Although the present invention has been described with reference toexemplary embodiments, it is not limited thereto. Those skilled in theart will appreciate that numerous changes and modifications may be madeto the preferred embodiments of the invention and that such changes andmodifications may be made without departing from the true spirit of theinvention. It is therefore intended that the appended claims beconstrued to cover all such equivalent variations as fall within thetrue spirit and scope of the invention.

1-21. (canceled)
 22. A method of fabricating dental restorations, themethod comprising: facilitating, by a server, communication between adental office and a dental laboratory, the communication comprising:transmitting by the dental office to the dental laboratory a scan filecomprising a scan of a patient; verifying, by the server, the scan filetransmitted by the dental office; receiving by the dental laboratory thescan file; transmitting by the dental laboratory to the dental officedesign characteristics for a designed dental restoration associated withthe scan file, wherein the design characteristics comprise data definingparameters for the designed dental restoration; verifying, by theserver, the design characteristics transmitted by the dental laboratory;receiving by the dental office the design characteristics forfabricating the designed dental restoration in accordance with thedesign characteristics; and verifying, by the server, the fabricateddesigned dental restoration; wherein each of the verifying steps arerelated to verifying authenticity and authorized relationships.
 23. Themethod of claim 22, wherein the design characteristics received by thedental office comprise at least one of: (i) a design file for use by afirst processor; and (ii) manufacturing specifications formulated by asecond processor.
 24. The method of claim 23, wherein the design filedefines the parameters for the designed dental restoration and iscreated by a computer-aided design (CAD) processor based upon the scanfile and a prescription provided by the dental office.
 25. The method ofclaim 24, wherein the prescription provided by the dental officecomprises one or more of: (i) a tooth number; (ii) a type of dentalrestoration; (iii) a restorative material; (iv) a shade for the designeddental restoration; and (v) a manufacturer.
 26. The method of claim 22,wherein verifying the scan file comprises confirming, by the server, atleast one of: (i) authenticity of the scan file; (ii) authenticity of aprescription associated with the scan file; and (iii) a pre-existingrelationship between the dental office and the dental laboratory; andwherein verifying the design characteristics comprises confirming, bythe server, at least one of: (i) authenticity of the designcharacteristics; and (ii) a pre-existing relationship between the dentallaboratory and the dental office.
 27. The method of claim 22, whereinverifying, by the server, the fabricated designed dental restoration,comprises: receiving, at the server from the dental office, informationassociated with the fabricated designed dental restoration; confirming,by the server, that that fabricated designed dental restorationsatisfies pre-determined conditions; transmitting, by the server, anauthentication of the fabricated designed dental restoration to thedental office; and printing, by an authentication processor, anauthentication indication associated with the fabricated designed dentalrestoration.
 28. A system for fabricating dental restorations, thesystem comprising: a server configured to facilitate communicationbetween a dental office and a dental laboratory, the communicationcomprising: a scan file transmitted by the dental office to the dentallaboratory, the scan file comprising a scan of a patient; designcharacteristics transmitted by the dental laboratory to the dentaloffice, the design characteristics for a designed dental restorationassociated with the scan file, wherein the design characteristicscomprise data defining parameters for the designed dental restoration;wherein the server is further configured to facilitate authenticationbetween the dental office and the dental laboratory, comprising:verifying the scan file transmitted by the dental office; verifying thedesign characteristics transmitted by the dental laboratory; andverifying a fabricated designed dental restoration in accordance withthe design characteristics; wherein each of the verifying steps arerelated to verifying authenticity and authorized relationships.
 29. Thesystem of claim 28, wherein the design characteristics received by thedental office comprise at least one of: (i) a design file for use by afirst processor; and (ii) specifications formulated by a secondprocessor.
 30. The system of claim 29, wherein the design file definesthe parameters for the designed dental restoration and is created by acomputer-aided design (CAD) processor based upon the scan file and aprescription provided by the dental office.
 31. The system of claim 30,wherein the prescription provided by the dental office comprises one ormore of: (i) a tooth number; (ii) a type of dental restoration; (iii) arestorative material; (iv) a shade for the designed dental restoration;and (v) a manufacturer.
 32. The system of claim 28, wherein verifyingthe scan file comprises the server confirming at least one of: (i)authenticity of the scan file; (ii) authenticity of a prescriptionassociated with the scan file; and (iii) a pre-existing relationshipbetween the dental office and the dental laboratory; and whereinverifying the design characteristics comprises the server confirming atleast one of: (i) authenticity of the design characteristics; and (ii) apre-existing relationship between the dental laboratory and the dentaloffice.
 33. The system of claim 28, wherein verifying the fabricateddental restoration comprises: receiving, at the server from the dentaloffice, information associated with the fabricated designed dentalrestoration; confirming, by the server, that that fabricated designeddental restoration satisfies pre-determined conditions; transmitting, bythe server, an authentication of the fabricated designed dentalrestoration to the dental office; and printing, by an authenticationprocessor, an authentication indication associated with the fabricateddesigned dental restoration.